A Singlet Oxygen Generator with Rapid Separation Process

Yu Qiang Dai; Zhen Dong Liu; Xiao Bo Xu; Wen Wu Chen; Li Zhi Zhu; Da Peng Hu

doi:10.4028/www.scientific.net/AMM.148-149.1223

Paper Titles

Strength Calculation Analysis of Diesel Engine Linkage Based on Three-Dimensional Contact Finite Element Method
p.1202

Experimental Research on a New-Type Concrete Antifreeze
p.1209

Theoretical Analysis for Storage Reliability of Underwater Vehicle
p.1214

Research on Friction Disk’s Surface Temperature Distribution and Oil Groove Configuration in Wet Friction Clutch
p.1218

A Singlet Oxygen Generator with Rapid Separation Process
p.1223

Determination the Heat Price of a Combined Heat and Power Plant with the Energy Grade Theory
p.1227

Research on the Braking System Control Strategy of Hybrid Electronic Bus
p.1231

Surface Treatment and Adhesive Interface Investigation of a New Type of Aluminum Lithium Alloy
p.1236

Macroscopy Lattice Deformation of Martensitic Transformation in Fe-Based Shape Memory Alloy
p.1240

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 148-149A Singlet Oxygen Generator with Rapid Separation...

A Singlet Oxygen Generator with Rapid Separation Process

Abstract:

Singlet oxygen generator is the heart of chemical oxygen iodine lasers and has been the focus of research for many years. In this paper, a novel singlet oxygen generator with rapid separation technology is briefly put forward. To ensure short residence time, the design of reaction and separation processes happening simultaneously in through-flow reactors is dumpy shaped. By means of computational fluid dynamics, the calculations indicate that the residence time of O2(1Δ) in the new structure is about 15ms and the new SOG has excellent anti-entrainment and defoaming separation performance. The analytical results show the new structure is a feasible and promising technology in singlet oxygen generation cases.

You might also be interested in these eBooks

Mechanical Engineering, Materials and Energy

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volumes 148-149)

Pages:

1223-1226

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.148-149.1223

Citation:

Cite this paper

Online since:

December 2011

Authors:

Yu Qiang Dai, Zhen Dong Liu, Xiao Bo Xu, Wen Wu Chen, Li Zhi Zhu, Da Peng Hu

Keywords:

Computational Fluid Dynamics (CFD), Rapid Separation, Residence Time Distribution, Singlet Oxygen Generator

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Kevin B. Hewett. Proceedings of SPIE 7131, 71310I (2008).

Google Scholar

[2] Gaurav Singhala, P.M.V. Subbaraob, et. al. Optics & Laser Technology , 39 (2007) 577-585.

Google Scholar

[3] Martin Huard, Cedric Briensy, Franco Berrutiz , Thierry A. Gauthier. International Journal of J Chemical Reactor Engineering, Vol. 8, (2010), pp.1-69.

Google Scholar

[4] Ross, Jr., J.L. and Schaub, C., Process and apparatus for separating fluidized cracking catalysts from hydrocarbon vapor, United States Patent: 5, 837, 129 (1998).

Google Scholar

[5] Nielsen, B.B., Berruti, F. and Behie, L.A., Riser terminator for internally circulating fluid bed reactor, United States Patent: 5, 665, 130 (1997).

Google Scholar

[6] Gauthier, T., Andreux, R., Verstraete, J., Roux, R. and Ross, J., International Journal of Chemical Reactor Engineering, Vol. 3, Article A47 (2005).

Google Scholar

[7] Hu Dapeng, Dai Yuqiang, et al. Supersonic condensation cyclone separators with cone core rod, China patent, CN2008100112158. 6, 2010. 2.

Google Scholar

[8] Tritton, D.J., Physical Fluid Dynamics, Van Nostrand Reinhold, 1977 (reprinted 1980).

Google Scholar

[9] Liou M. -S. and Steffen, Jr., C. J.: Journal of Computational Physics, Vol. 107 (1993), pp.23-39.

Google Scholar

[10] D.Y. Peng, D.B. Robinson: Ind. Eng. Chem. Fundam. Vol. 15(1976), pp.59-64.

Google Scholar

[11] Orbey, S.I. Sandler, and D.S. Wong. Fluid Phase Eq. Vol. 85(1993), pp.41-54.

Google Scholar